U.S. patent number 5,754,932 [Application Number 08/637,343] was granted by the patent office on 1998-05-19 for image forming apparatus having convey belt.
This patent grant is currently assigned to Canon Kabushiki Kaisha. Invention is credited to Motoaki Tahara.
United States Patent |
5,754,932 |
Tahara |
May 19, 1998 |
**Please see images for:
( Certificate of Correction ) ** |
Image forming apparatus having convey belt
Abstract
An image forming apparatus comprises a convey belt for bearing
and conveying a recording material, image forming means for forming
an image on the recording material born on the convey belt, a
detection means for detecting a position of the convey belt in a
direction perpendicular to a recording material conveying direction
provided by the convey belt, count means for effecting a counting
operation in accordance with a detection output from the detection
means, rocking means for rocking the convey belt in the direction
perpendicular to the recording material conveying direction, and
control means for controlling a rocking operation of the rocking
means on the basis of a counted value from the count means.
Inventors: |
Tahara; Motoaki (Yokohama,
JP) |
Assignee: |
Canon Kabushiki Kaisha (Tokyo,
JP)
|
Family
ID: |
14434828 |
Appl.
No.: |
08/637,343 |
Filed: |
April 25, 1996 |
Foreign Application Priority Data
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|
|
|
|
Apr 28, 1995 [JP] |
|
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7-106487 |
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Current U.S.
Class: |
399/303; 399/299;
399/312; 399/395 |
Current CPC
Class: |
G03G
15/0194 (20130101); G03G 2215/0116 (20130101) |
Current International
Class: |
G03G
15/01 (20060101); G03G 015/01 () |
Field of
Search: |
;399/66,165,297,298,299,301,303,310,311,312,313,316,388,394,395
;198/807,806 |
References Cited
[Referenced By]
U.S. Patent Documents
Primary Examiner: Brase; Sandra L.
Attorney, Agent or Firm: Fitzpatrick, Cella, Harper &
Scinto
Claims
What is claimed is:
1. An image forming apparatus comprising:
a convey belt for bearing and conveying a recording material;
an image forming means for forming an image on the recording
material born on said convey belt;
detection means for detecting a position of said convey belt in a
direction perpendicular to a recording material conveying direction
provided by said convey belt;
count means for counting a time period in which said convey belt is
located out of a predetermined area in a direction perpendicular to
the convey direction based on a detected output from said detection
means;
rocking means for rocking said convey belt in the direction
perpendicular to the recording material conveying direction;
and
control means for controlling a rocking operation of said rocking
means based on a counted value of said count means.
2. An image forming apparatus according to claim 1, wherein said
control means judges whether the rocking operation of said rocking
means is effected on the basis of said counted value, and wherein
an interval between the rocking operation of said rocking means and
the next rocking operation is increased as the number of rocking
operations of said rocking means is increased.
3. An image forming apparatus according to claim 1, wherein said
rocking means rocks a shaft for supporting said convey belt.
4. An image forming apparatus according to claim 3, wherein said
rocking means includes a pulse motor.
5. An image forming apparatus according to claim 3, wherein said
rocking means increases tilt of a shaft supporting said convey belt
as the counted value increases to move said convey belt in one of
the directions perpendicular to the conveying direction.
6. An image forming apparatus according to claim 1, wherein said
rocking means includes a pulse motor.
7. An image forming apparatus according to claim 1, further
comprising a second control means for controlling to increase the
number of rocking operations of said rocking means when a rocking
speed of said convey belt exceeds a predetermined value, in
comparison with when said rocking speed is smaller than said
predetermined value.
8. An image forming apparatus according to claim 1, wherein said
detection means comprises a first sensor disposed in the vicinity
of one end of said convey belt in the direction perpendicular to
the recording material conveying direction, and a second sensor
disposed in the vicinity of the other end of said convey belt in
the direction perpendicular to the recording material conveying
direction.
9. An image forming apparatus according to claim 8, further
comprising a second control means for controlling to increase the
number of rocking operations of said rocking means when a rocking
speed of said convey belt exceeds a predetermined value, in
comparison with when said rocking speed is smaller than said
predetermined value.
10. An image forming apparatus according to claim 1, wherein said
image forming means includes an image bearing member, and a
transfer means for transferring the image from said image bearing
member to the recording material born on said convey belt.
11. An image forming apparatus according to claim 10, wherein said
image bearing member comprises an electrophotographic
photosensitive member.
12. An image forming apparatus according to claim 1, wherein said
image forming means includes a plurality of image bearing members,
and transfer means for transferring the images from said plural
image bearing members to the recording material born on said convey
belt in a superimposed fashion.
13. An image forming apparatus according to claim 12, wherein said
image bearing member comprises an electrophotographic
photosensitive member.
14. An image forming apparatus according to claim 1, a rocking
force of said convey belt by said rocking means is variably
controlled based on the counted value.
15. An image forming apparatus according to claim 14, wherein the
rocking force increases as the counted value increases.
16. An image forming apparatus according to claim 1, wherein said
control means determines whether to perform the rocking operation
by said rocking means based on the counted value or not.
17. An image forming apparatus according to claim 16, wherein said
control means performs the rocking operation by said rocking means
when the counted value is larger than the predetermined value, but
does not perform it when the counted value is smaller than the
predetermined value.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to an image forming apparatus having
a convey belt for bearing and conveying a recording material, and
more particularly, it relates to an image forming apparatus
suitable to be applied to a color copying machine, a laser beam
printer and the like, in which images formed on a plurality of
image bearing members are transferred onto a recording material
born by a convey belt in a superimposed fashion.
2. Related Background Art
FIG. 16 is a sectional view of a conventional image forming
apparatus (for example, digital color copying machine).
In the digital copying machine, a latent image is formed on a
photosensitive drum 1301 by laser exposure 1303, and then, the
latent image is developed by color toner to form a visualized toner
image. The developed toner image is transferred onto a transfer
sheet (recording material) born on a transfer drum 1302. By
repeating operation from the laser exposure process to the transfer
process in color order (yellow, magenta, cyan and black), a
full-color image is formed on the. transfer sheet by superimposing
the color toner images. In such an apparatus, since the transfer
sheet is fixed to the transfer drum 1302, when the color toner
images are transferred onto the transfer sheet in the superimposed
fashion, there is no color deviation in a main scan direction.
However, in image forming apparatuses in which a plurality of
photosensitive members are disposed side by side and images formed
on the photosensitive members are successively transferred onto a
transfer sheet conveyed by a transfer belt to obtain a full-color
image, since the image is transferred onto the transfer sheet while
always forming the images on the plurality of photosensitive
members, after belt deflection along a direction perpendicular to a
transfer sheet conveying direction is detected, if a belt
deflection direction is abruptly changed, positions on which the
color toner images are transferred are changed, with the result
that the color deviation occurs in the direction perpendicular to
the transfer sheet conveying direction, thereby deteriorating the
image.
SUMMARY OF THE INVENTION
An object of the present invention is to provide an image forming
apparatus which can prevent image-shift (color deviation) which may
be caused when a rocking direction of a convey belt is changed in a
direction perpendicular to a recording material conveying
direction.
Another object of the present invention is to provide an image
forming apparatus which can rock a convey belt not to cause
image-shift on a recording material born on a convey belt.
The other objects and features of the present invention will be
apparent from the following detailed explanation of the invention
referring to the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is an explanatory view showing an image forming apparatus
according to a preferred embodiment of the present invention;
FIG. 2 is a sectional view for explaining an image forming process
of an image forming station of the image forming apparatus of FIG.
1;
FIG. 3 which is comprised of FIGS. 3A and 3B is an explanatory view
showing an image process circuit portion of the image forming
apparatus of FIG. 1;
FIG. 4 is a block diagram for explaining an image data treating
condition of a printer portion of the image forming apparatus of
FIG. 1;
FIG. 5 is an explanatory view showing a positional relation between
photosensitive drums in the printer portion of the image forming
apparatus of FIG. 1;
FIG. 6 is a timing chart showing exposure timings of sub-scans for
exposing the photosensitive drums of FIG. 5;
FIG. 7 is a block diagram showing an example of a circuit for
generating sub-scan enable signals;
FIG. 8 is a block diagram of a bus selector shown in FIG. 3A;
FIG. 9 is a plan view showing a transfer belt of FIG. 1 and
therearound in detail;
FIG. 10 is a view showing a detection sensor for detecting belt
deflection;
FIG. 11 is a flow chart showing measuring and treating a belt
deflection time in the image forming apparatus according to the
present invention;
FIG. 12 is a flow chart showing a belt front end detect routine
shown in FIG. 11 in detail;
FIG. 13 is a flow chart showing a belt rear end detect routine
shown in FIG. 11 in detail:
FIG. 14 is a view showing the correspondence between a rocking
trace of the transfer belt end shown in FIG. 9 and outputs of
detection sensors;
FIG. 15 is a view showing a relation between the number of
operations of a pulse motor shown in FIG. 9 and threshold values;
and
FIG. 16 is a sectional view of a conventional image forming
apparatus.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
An embodiment of an image forming apparatus according to the
present invention will now be explained with reference to the
accompanying drawings.
[Image Forming Process]
FIG. 1 schematically shows an image forming apparatus according to
a preferred embodiment of the present invention. In this
embodiment, the digital image forming apparatus for forming a
full-color image by using four colors, i.e., yellow, magenta, cyan
and black and includes four image forming stations 1Y, 1M, 1C, 1K
which correspond to yellow, magenta, cyan and black, respectively
and which are disposed side by side.
FIG. 2 is a sectional view for explaining an image forming process
of the image forming station shown in FIG. 1. Now, the image
forming process will be explained with reference to an yellow image
forming station as an example.
In the yellow image forming station, a photosensitive drum (image
bearing member) 201a is uniformly charged by a first high voltage
charger and grid high voltage unit 203a. After the charging, in
response to image information, the photosensitive drum 201a is
exposed by laser light scanned by a laser scanner 120 to form a
latent image for an yellow image. Then, the latent image
corresponding to the yellow image information is developed by a
developing device 204a including yellow color toner to form an
yellow toner image. The toner image is transferred onto a transfer
material (transfer sheet) born on a recording material transfer
belt, i.e., convey belt (recording material convey means) 108 by a
transfer charger 205a.
Residual toner remaining on the yellow photosensitive drum is
removed by a cleaning device 206a. Incidentally, similar image
forming processes are performed in the magenta, cyan and black
image forming stations 1M, 1C, 1K, but, detailed explanation
thereof will be omitted.
[Both-Face Image Forming Sequence]
A both-face image forming sequence of the image forming apparatus
will be described referring to an example that the transfer sheet
is supplied from an upper cassette.
As soon as an image formation start signal is emitted, a first
sheet supply roller solenoid (not shown) is turned ON so that the
transfer sheet P starts to be supplied from a sheet supply cassette
101a. The transfer sheet P supplied from the sheet supply cassette
101a is conveyed by pairs of convey rollers 102, 103 to reach a
first pair of regist rollers 104. The transfer sheet 9 is
temporarily stopped when a predetermined loop is formed in the
sheet after a tip end of the sheet abuts against a nip of the
regist rollers 104.
On the other hand, at the same time when the image formation start
signal is emitted, an original on a platen is read by a CCD 105,
and an image signal corresponding to the read image is sent to an
image process portion 106. When image data read in an image memory
of the image process portion 106 becomes a laser scan permitting
condition, the first pair of regist rollers 104 start to be
rotated.
By rotation of the regist rollers, the transfer sheet P is conveyed
to a predetermined position on the transfer belt 108 and is adhered
to there for image formation.
As mentioned above, the different color toner images are
transferred onto the transfer sheet P. In this case, the image
information of the original is written on the respective
photosensitive drums at such timings that the toner images are
successively transferred onto the transfer sheet P in a
superimposed fashion when the transfer sheet P passes through the
yellow, magenta, cyan and black image forming stations 1Y, 1M, 1C
and 1K, respectively.
The transfer sheet P which was passed through four image forming
stations successively and to which four toner images were
transferred in the superimposed fashion is then conveyed by a
pre-fixing convey belt 107 to a fixing device 109, where the toner
images are fixed.
On the other hand, in a both-face copy mode, at the same time when
the image formation start signal is emitted, a sheet re-supply
pick-up roller solenoid (not shown) is turned ON to lift a sheet
re-supply roller 110 for preparing for both-face image formation.
Further, a sheet convey path deflection plate solenoid (not shown)
is also turned ON, with the result that a first sheet deflection
plate 111 is operated to form a sheet convey path for the both-face
image formation. At the same time, a sheet stopper solenoid SL (not
shown) associated with an intermediate tray portion 112 is turned
ON, with the result that a sheet stopper plate (not shown) in the
intermediate tray portion is operated.
After the fixing operation regarding a first surface of the
transfer sheet is finished, the transfer sheet P is conveyed by the
first sheet deflection plate 111 to a pair of convey rollers 113
through a both-face convey path. When the transfer sheet P is
passed through a sheet reverse rotation detection sensor 115
disposed in the vicinity of a switch-back portion (sheet reverse
rotation portion) 114, a reversible roller 116 is rotated in a
reverse direction.
As a result, the transfer sheet P is switched-back to be conveyed
to a second convey portion. Sheet size deflection plates 117, 118
serve to change the transfer sheet convey path to the intermediate
tray 112 by driving a sheet deflection plate solenoid SL7 or SL8
(not shown).
When the first transfer sheet P is conveyed into the intermediate
tray, the sheet re-supply pick-up solenoid (not shown) is turned
OFF temporarily, thereby lowering the rotating sheet re-supply
roller 110 on the transfer sheet P. As a result, the transfer sheet
P abuts against the sheet stopper plate (not shown).
By the above-mentioned series of operations, the transfer sheets
each having a first surface on which the image was formed are
successively stacked on the intermediate tray 112 for preparation
for second surface image formation.
In a condition that the sheet re-supply roller 110 is lowered and
contacted with an upper surface of the transfer sheets 9 stacked on
the tray 112, when a second surface image formation start signal is
emitted, the second surface image formation is started. That is to
say, a sheet re-supply clutch (not shown) is turned ON to rotate
the sheet re-supply roller 110, thereby re-supplying one transfer
sheet P in the tray from an uppermost one. When the first transfer
sheet P is re-supplied, the sheet re-supply roller 110 is
lifted.
And, when the re-supply of the first transfer sheet P is finished,
the rotating sheet re-supply roller 110 is lowered at a
predetermined timing to supply a next (second) transfer sheet. The
sheet re-supply roller 110 repeats such lifting and lowering
movements. The re-supplied transfer sheet P is conveyed by the pair
of convey rollers 103 to reach the nip between the pair of regist
rollers 104. After a predetermined loop is formed in the transfer
sheet, the paired convey rollers 103 are stopped temporarily.
Thereafter, the transfer sheet is conveyed to and adhered on the
transfer belt 108 at a predetermined timing, as is in the first
surface image formation. Then, the transfer sheet is passed through
the first to fourth image forming stations 1Y, 1M, 1C, 1K to form a
second image on the other (second) surface of the transfer sheet.
Then, the second image is fixed in the fixing device.
On the other hand, when the second image formation is started,
since the first sheet deflection solenoid (not shown) is turned
OFF, the transfer sheet on which the second image was formed and in
which the second image was fixed is directed to a pair of discharge
rollers, and then is discharged onto a discharge tray. After a last
transfer sheet was discharge, the image forming operation is
finished.
[Image Process Portion]
FIGS. 3A and 3B are explanatory views for explaining the
construction of the image process portion shown in FIG. 4. Now, the
construction and operation of the image process portion will be
explained. Incidentally, FIGS. 3A and 3B show flows of the image
signal (electric signal) from the reading of the CCD 105 to the
output as a print signal.
The image data photo-taken by the CCD 105 is sample-held by an A/D
& S/H circuit 302. Then, the image data is A/D-converted to
generate RGB three color digital signals. The color-decomposed data
are subjected to shading correction and black correction in a
shading circuit 303, and then are subjected to NTSC correction in
an input masking circuit 304. Then, the data are subjected to
magnify process (enlarge/contraction) in a magnify process circuit
305, and then are sent to an image data compress portion 309.
In the compress portion 309, the image is compressed by an encoder
portion 306 for compressing the image data, and the compressed
image data is stored in a memory portion 307. The image data
compressed and stored in the memory portion 307 are read in an
enlarged form by an decoder portion 308 to generate signals 313 to
316 corresponding to toner signals used in the printer. The read
image data are subjected to prearrangement treatment and masking
treatment in a masking UCR circuit 310 and then are
.gamma.-converted in a .gamma.-correction circuit 311, and then are
subjected to edge emphasis in an edge emphasis circuit 312. Then,
the data are sent to the printer portion.
Incidentally, in the illustrated embodiment, in order to achieve
simultaneous drive function, there is provided a function for
effecting signal-communication between the printer and external
(another) devices.
When the signal is outputted to the another device, after the
magnify process, signals 320 to 322 and signals 323 such as image
synchronous signals VCLK, HSYNC, VE and the like are passed through
a bus selector 317 and then are combined with a simultaneous drive
control signal 325. The combined signal is sent to another devices
327, 328 through an external bus 326.
Further, when a signal is received from another device, the signal
sent through the external bus 326 is introduced into the encoder
portion 306 through the bus selector 317. A communicate circuit 318
for simultaneous drive utilizes four lines (communication lines and
control lines) to effect communication between the circuit 318 and
the external device(s), thereby achieving the synchronism of
various sequences and communication of information.
FIG. 4 is a block diagram for explaining the image data processing
condition of the printer portion shown in FIG. 1.
The Y (yellow), M (magenta), C (cyan) and K (black) image signals
sent from the reader portion shown in FIG. 1 are .gamma.-corrected
by .gamma.-correction circuits 401a to 401d in accordance with
sensitivity of the photosensitive drums. Thereafter, the image data
Y and the image data M are synchronized with each other by FIFO
circuits 402a, 402b. Regarding the image data C and the image data
K, since they are scanned by the laser scanner 120 in a
mirror-image fashion, main scan data thereof are inverted
(reversely rotated) by LIFO circuits 403a, 403b to achieve the
synchronism. Thereafter, the color image signals are pulse-width
modulated by pulse width modulate circuits 404a to 404d. In
response to the modulated image signals, laser drivers 405a to 405d
are driven as lasers.
[Image Synchronous Control]
FIG. 5 is a sectional view showing a positional relation between
the photosensitive drums 201a to 201d of the printer portion shown
in FIG. 1.
As shown in FIG. 5, the photosensitive drums are disposed side by
side with a distance d1, and the transfer belt 108 conveys the
transfer sheet P at a speed of Vb. By laser scan systems 202a to
202d, in response to the image information for respective colors,
the photosensitive drums are exposed by the image light beams
corresponding to the respective colors. Now, it is assumed that a
distance from an image exposure position on the Y (yellow)
photosensitive drum 201a and a contact position between the drum
and the transfer belt is d3 and a distance from the nip of the
regist rollers 104 to a center of the Y photosensitive drum 201a is
d2.
Regarding this case, FIG. 6 shows exposure timings of sub-scans for
exposing the photosensitive drums in such a manner that the image
information of the original stored in the memory is successively
transferred onto the transfer sheet in a superimposed fashion when
the transfer sheet passes through the yellow (Y), magenta (M), cyan
(C) and black (K) image forming stations.
FIG. 6 is a timing chart showing the exposure timings of sub-scans
for exposing the photosensitive drums shown in FIG. 5.
In order to send the transfer sheet stopped by the regist rollers
104 to the transfer belt 108, an image pattern formation start
signal is emitted at the same time when the regist rollers are
driven. After the image pattern formation signal rises, enable
signals (Y, M, C, K) rise at timings obtained from equations
Ty=(d2-d3)/Vb, Tm=Ty+d1/Vb, Tc=Ty+2d1/Vb and Tk=Ty+3d1/Vb,
respectively, and fall in accordance with a length of the transfer
sheet in a sub-scan direction.
FIG. 7 is a block diagram showing an example of a circuit for
generating the sub-scan enable signals shown in FIG. 6.
Incidentally, in the illustrated embodiment, the time is counted by
utilizing HSYNC in which one clock is generated whenever one-line
is scanned.
In FIG. 7, a 14-bit counter 701 serves to count the number of
HSYNCs in synchronous with main scan synchronous HSYNC. A register
702 serve to store a value loaded in the counter when an LOAD
signal is generated, and data is written in the register by a CPU.
In the illustrated embodiment, data "0" is written.
Comparators 703a to 703d serve to compare rising times of color
image enable signals with each other. The count numbers of HSYNCs
corresponding to the enable signals Ty, Tm, Tc, Tk are written in
registers 704a to 704d for defining the rising times of the color
sub-scan enable signals by the CPU, and, when the count coincides
with the output of the 14-bit counter 701, a coincidence signal is
emitted.
Comparators 705a to 705d serve to compare falling times of color
image enable signals with each other. The count numbers of HSYNCs
corresponding to the enable signals Ty, Tm, Tc, Tk are written in
registers 706a to 706d for defining the falling times of the color
sub-scan enable signals by the CPU, and, when the count coincides
with the output of the 14-bit counter 701, a coincidence signal is
emitted. When the length of the transfer sheet is L, a time
duration Tp during which the enable signal is risen is represented
by Tp=L/Vb.
Thus, values obtained by adding numerical values converted from Tp
into HSYNC number to the values stored in the registers 704a to
704d are written in the registers 706a to 706d.
The image pattern formation start signal shown in FIG. 6 is
inputted to an input CNT START of a flip-flop 708 shown in FIG. 7.
The rising signal of the image pattern formation start signal is
caught by two flip-flops 708, 709 and then is inputted to an input
LOAD (LD) of the counter 701, thereby making the counter 701 clear
for preparing the counting operation. The HSYNC numbers are
successively counted by the counter 701. When the count value
corresponding to the rise of the yellow (Y) enable signal is
reached, the comparator 703a detects the coincidence and emits the
coincidence signal.
The coincidence signal is inputted to a J terminal of a JK
flip-flop 707a, so that the yellow (Y) sub-scan enable signal rises
to a HI level. When the count is continued and the count value
corresponding to the fall of the enable signal is reached, the
comparator 705a detects the coincidence and emits the coincidence
signal. The coincidence signal is inputted to a K terminal of a JK
flip-flop 707a, so that the yellow (Y) sub-scan enable signal falls
to a LOW level. Regarding magenta, cyan and black colors, sub-scan
enable signals are generated in the same manner as the yellow
sub-scan enable signal.
In the illustrated embodiment, the image forming apparatus has a
simultaneous drive function for permitting the communication of
image and/or information between devices by interconnecting a
plurality of devices, so that an image scanned by a master device
can be outputted from a slave device.
FIG. 8 is a block diagram for explaining the bus selector 317 shown
in FIG. 3A. The bus selector 317 controls the flow of the image
information between the devices on the basis of the image signal
and image synchronous signal.
When any device is operated as a slave device under the control of
the CPU, a signal line 803 is controlled to bring a signal on the
line to a HI level so that the image signal and image synchronous
signal can be inputted from outside to inside. On the other hand,
when any device is operated as a master device, the signal on the
line 803 is brought to a LOW level by the CPU so that the image
signal and image synchronous signal can be inputted from inside to
outside.
[Belt Deflection Detection and Belt Deflection Control]
FIG. 9 is a plan view showing the transfer belt shown in FIG. 1 and
therearound.
In FIG. 9, there are provided sensors 901, 902 for detecting
lateral edges of the belt to detect the belt deflection in a
direction perpendicular to a transfer sheet conveying direction.
Now, the sensor disposed at a front side of the apparatus is called
as a belt front end detection sensor 901 and the sensor disposed at
a rear side of the apparatus is called as a belt rear end detection
sensor 902.
A motor shaft of a pulse motor 903 for controlling the belt
deflection is connected to a transfer belt convey shaft 904 for
conveying the transfer belt 108. The pulse motor 903 is controlled
in such a manner (which will be described later) that, when a
length of the motor shaft of the pulse motor is changed, the
inclination angle of the convey shaft 904 pivotally supported at
one end C are changed as shown by the arrow A, thereby changing the
shifting direction of the belt. Incidentally, the symbol CONT
denotes a control portion including a CPU, a ROM and a RAM
including a counter.
FIG. 10 shows the belt front end detection sensor 901 and the belt
rear end detection sensor 902 in detail.
As shown in FIG. 10, each of the detection sensors 901, 902
includes an actuator 905 and a photo-interrupter 906. If the
transfer belt 108 is shifted toward the front side of the image
forming apparatus, the actuator 905 is urged by the lateral edge of
the belt. As a result, the photo-interrupter 906 detects the
passing of light, thereby detecting the deflection of the belt.
Next, the summary of the illustrated embodiment will be described
with reference to FIGS. 9 and 10.
In the image forming apparatus, there are provided a plurality of
image forming stations disposed side by side and including a latent
image forming means (laser scanner 120) for scanning photosensitive
members with laser beams to-form latent images and a developing
means (developing device 204a and the like) for developing, with
toner, the latent images formed on the photosensitive members to
form color toner images, and a convey means (transfer belt 108) for
conveying a transfer sheet, whereby a full-color image is formed by
transferring the color toner images formed in the image forming
stations onto the transfer sheet conveyed by the convey means in a
superimposed fashion. The image forming apparatus further comprises
a plurality of detection means (detection sensors 901, 902) for
detecting the belt deflection of the convey means in a
sub-direction perpendicular to a convey direction of the convey
means, a counting means (counter in the control portion CONT) for
effecting a counting operation in accordance with an output from
the detection means, a rocking drive means (pulse motor 903) for
rocking a convey shaft of the convey means for a predetermined
amount, and a control means (CPU in the control portion CONT) for
controlling the rocking of the rocking drive means on the basis of
the comparison between the counted value counted by the counting
means and a threshold value (stored in ROM of the control portion
CONT), whereby the rocking of the rocking drive means (pulse motor
903) is controlled by the control portion CONT on the basis of the
comparison between the counted value (time period during which the
belt deflection is being detected by the detection means 901, 902)
of the counter and the stored threshold value, so that the belt
deflection is gradually corrected to return the convey belt to its
normal position without causing transfer-shift (transfer
deviation).
Further, in the image forming apparatus, the control means (CPU in
the control portion CONT) controls the pulse motor 903 in such a
manner that the transfer belt is rocked by a predetermined amount
on the basis of the counted value counted by the counting means and
the threshold values (FIG. 15) having different intervals depending
upon the number of rocking operation, thereby gradually correcting
the belt deflection to return the convey belt to its normal
position while changing the rocking interval without causing
transfer-shift.
In the image forming apparatus, the pulse motor 903 rocks the
convey shaft 904 for conveying the transfer belt 108 in directions
shown by the arrow A in FIG. 9 so that the belt deflection can be
corrected by changing the shifting direction of the transfer belt.
Incidentally, by rocking the convey shaft, the convey shaft is
inclined with respect to the conveying direction by a predetermined
angle.
In the image forming apparatus, the rocking drive means is
constituted by a pulse motor 903 such as a stepping motor so that
the rocking amount of the convey shaft for the transfer belt 108
can be controlled with high accuracy.
In the image forming apparatus, there are further provided a
calculation means (CPU in the control portion CONT) for calculating
a deflecting speed of the convey means on the basis of the time
period during which the belt deflection is being detected by the
detection sensor 901 or 902, and a recovery means (CPU in the
control portion CONT) for correcting the rocking amount of the
rocking drive means rocked by the control means on the basis of
comparison between the deflecting speed calculated by the
calculation means and a predetermined deflection speed (and for
recovering the rocking amount within a predetermined deflecting
speed) range, whereby the rocking amount of the rocking drive means
rocked by the control means is corrected by the recovery means to
recover the deflecting speed within the predetermined deflecting
speed range on the basis of the comparison result between the
deflecting speed calculated by the calculation means and the
predetermined deflecting speed, so that, even when the deflecting
speed of the transfer belt 108 is fast, the belt deflection is
gradually corrected to return the convey belt to its normal
position swiftly while changing the rocking interval without
causing transfer-shift.
[Belt Deflection Control]
FIG. 11 is a flow chart showing a program for measuring a belt
deflection time in an image forming apparatus according to the
present invention. The belt deflection time measuring program
generally includes four routines, i.e., (1) belt front end detect
routine, (2) belt rear end detect routine, (3) belt counter renewal
routine, and (4) predetermined time wait routine. Incidentally, the
belt detection operation of the sensor is effected every 0.1
sec.
FIG. 12 is a flow chart showing the belt front end detect routine
shown in FIG. 11 in detail. Incidentally, (1) to (9) indicate
steps.
In FIG. 12, first of all, it is judged whether the belt is detected
by the belt front end detection sensor 901 (step 1). If the belt is
detected by the sensor, it is judged whether the belt front end
detection flag is "1" or not (step 2). If the belt front end
detection flag is "1", since it means that the belt is already
detected by the sensor 901, the program goes to a step 6.
On the other hand, in the step 2, if it is judged that the belt
front end detection flag is "0", since it means that the belt is
not detected by the previous detecting operation of the sensor 901
and the belt is shifted from the centered position toward the front
side this time, the belt front end detection flag is set to "1"
(step 3), and a belt rear end detection flag is set to "0" (step
4).
Then, a recovery check for effecting recovery treatment for driving
the rock motor (pulse motor) when the shifting speed of the belt
from the rear side to the front side is faster than a predetermined
value is executed (step 5). The recovery check will be described
later.
Then, the belt front end detection counter is renewed or revised by
"1" (step 6), and, it is judged whether the detected value of the
belt front end detection sensor is equal to a threshold value Xf
(step 7). If not equal, the program is ended. Whereas, if equal,
the CPU drives the pulse motor in a clockwise direction for a time
duration T2 not affecting an influence upon the image (step 8).
That is to say, the detecting operation of the sensor is effected
every predetermined time (0.1 sec in the illustrated embodiment),
and, whenever the belt front end is detected, the counter is
renewed, and, only when the counted value of the counter becomes
equal to the predetermined value (i.e., only when the time duration
during which the belt front end is detected reaches the
predetermined value), the pulse motor is driven. After the pulse
motor is driven, a next threshold value Xf is revised.
Incidentally, the detailed values of the threshold will be
described later.
FIG. 13 is a flow chart showing the belt rear end detect routine
shown in FIG. 11 in detail. Incidentally, (1) to (9) indicate
steps. Further, as mentioned above, the belt detection operation of
the sensor is effected every 0.1 sec.
In FIG. 13, first of all, it is judged whether the belt is detected
by the belt rear end detection sensor 902 (step 1). If the belt is
detected by the sensor, it is judged whether the belt rear end
detection flag is "1" or not (step 2). If the belt rear end
detection flag is "1", the program goes to a step 6.
On the other hand, in the step 2, if it is judged that the belt
rear end detection flag is "0", since it means that the belt is
shifted from the centered position toward the rear side, the belt
rear end detection flag is set to "1" (step 3), and the belt front
end detection flag is set to "0" (step 4).
Then, a recovery check for effecting recovery treatment for driving
the rock motor (pulse motor) when the shifting speed of the belt
from the front side to the rear side is faster than a predetermined
value is executed (step 5). The recovery check will be described
later.
Then, the belt rear end detection counter is renewed or revised by
"1" (step 6), and, it is judged whether the detected value of the
belt rear end detection sensor is equal to a threshold value Xb
(step 7). If not equal, the program is ended. Whereas, if equal,
the CPU drives the pulse motor in a counter-clockwise direction for
a time duration T2 not affecting an influence upon the image (step
8). Then, a next threshold value Xb is revised. Incidentally, the
detailed value of the threshold will be described later.
[Belt Rocking Pulse Motor Driving Time Threshold Values]
As mentioned above, an interval between a certain threshold value
for determining the timing for driving the belt rocking pulse motor
903 and a next threshold value is varied with the total time period
during which the belt end is being detected and the belt rocking
pulse motor driving time period.
The reason why the drive timing is determined on the basis of the
total time period during which the belt end is being detected will
be explained.
FIG. 14 is a view showing the correspondence between the rocking
trace of the belt end and the outputs of the detection sensors.
As shown in FIG. 14, even if the belt is once shifted from the side
position to the centered position not to be detected by the
detection sensor, the belt end may be detected by the sensor
again.
The reason is that the belt is not always shifted to a given
direction at a constant speed as shown in FIG. 14, but may be
shifted along a hysteresis loop or the belt end shifting trace may
be varied with the position of the belt end. In this way, when the
fact that, after the rocking direction of the belt is once changed,
the belt may be returned again is taken into consideration, it is
preferable, for the correct control, that the pulse motor driving
time period is changed by using the total detection value of the
belt end detection sensors.
FIG. 15 shows a relation between the number of motor operations and
the threshold values.
Incidentally, as mentioned above, the time counter utilizes the
total detection value of the belt end detection sensors. Briefly
explaining, when the belt is initially detected by the sensor,
first of all, the motor is driven, and, in the next time, when the
value of the belt end detection counter reaches "50", the motor is
driven again. Similarly, the motor is driven when the counter value
reaches "150", "400", . . . , respectively. According to the
illustrated embodiment, the interval between a given threshold
value and the next threshold value is increased as the number of
motor operations is increased.
[Recovery Treatment Check]
When the rocking speed of the belt is fast, even when the pulse
motor is driven in the normal sequence as mentioned above, since it
takes a relatively long time to change the rocking direction of the
belt, in the illustrated embodiment, the recovery treatment is
performed in accordance with the rocking speed.
More specifically, on the basis of the belt rocking speed time
periods Tfb (from front end to rear end) and Tbf (from rear end to
front end), the following calculations are carried out. When the
belt rocking time period T is long, i.e., when the rocking speed is
slow (T>Tth), P=0; whereas, when the belt rocking time period T
is short, i.e., when the rocking speed is high (T.ltoreq.Tth),
P=C(Tth-T)+Pinit. Where, P is the number of pulses when the motor
is driven exceptionally, C is constant, Tth is a threshold time
derived from a rocking time design average value of the belt, and T
is a detected belt rocking time period (Tfb or Tbf) wherein Tfb is
used when the belt is being shifted from the front side to the rear
side (upper side to lower side in FIG. 9) and Tbf is used when the
belt is being shifted from the rear side to the front side.
Further, Tinit (predetermined number of pulses driven every time)
means the number of pulses driven when the detected time period T
is smaller than Tth and is previously determined in consideration
of the feature of the apparatus.
For example, the belt rocking speed time period Tfb is calculated
as follows.
By subtracting a time duration Tf2 during which the belt is
continuously detected by the front end detection sensor 901 from a
time duration Tf1 from when the transfer belt 108 shifted from the
centered position toward the front side is detected by the front
end detection sensor 901 to when the belt returned toward the
centered position is detected by the rear end detection sensor 902,
the belt rocking speed time period Tfb can be obtained (i.e.,
Tfb=Tf1-Tf2). This time period physically represents a time period
during which the belt is being shifted from the front side to the
rear side.
Similarly, the belt rocking speed time period Tbf is calculated as
follows.
By subtracting a time duration Tb2 during which the belt is
continuously detected by the front end detection sensor 901 from a
time duration Tb1 from when the transfer belt 108 shifted from the
centered position toward the rear side is detected by the rear end
detection sensor 902 to when the belt returned toward the centered
position is detected by the front end detection sensor 901, the
belt rocking speed time period Tbf can be obtained (i.e.,
Tbf=Tb1-Tb2). This time period physically represents a time period
during which the belt is being shifted from the front side to the
rear side.
By the above calculations, if the rocking speed of the belt is
faster than the predetermined value, when the belt end is detected,
the motor 903 is driven exceptionally by P pulses more than the
normal condition, thereby effecting the exceptional treatment
(recovery treatment). On the Other hand, when the rocking speed of
the belt is slower than the predetermined value, the recovery
treatment (for driving the motor exceptionally) is not
performed.
Next, the summary of the illustrated embodiment will be described
with reference to FIGS. 12 and 13.
In the image forming apparatus, there are provided a plurality of
image forming stations disposed side by side and including a latent
image forming means (laser scanner 120) for scanning photosensitive
members with laser beams to form latent images and a developing
means (developing device 204a and the like) for developing, with
toner, the latent images formed on the photosensitive-members to
form color toner images, and a convey means (transfer belt 108) for
conveying a transfer sheet, whereby a full-color image is formed by
transferring the color toner images formed in the image forming
stations onto the transfer sheet conveyed by the convey means in a
superimposed fashion. The image forming apparatus performs a
detecting step (steps 1, 2 in FIGS. 12 and 13) for detecting the
belt deflection of the convey means in a sub-direction
perpendicular to a convey direction of the convey means, a counting
step (steps 1, 2 in FIGS. 12 and 13) for counting the time period
during which the deflection condition is being detected, a
comparing step (steps 7 in FIGS. 12 and 13) for comparing the
counted value and a stored threshold value, a rocking step (steps 8
in FIGS. 12 and 13) for rocking a rocking drive means on the basis
of the comparison, and a renewal step (steps 9 in FIGS. 12 and 13)
for revising the threshold value, whereby the belt deflection is
gradually corrected to return the convey belt to its normal
position without causing transfer-shift (transfer deviation).
In the image forming apparatus, a calculating step (steps 5 in
FIGS. 12 and 13) for calculating a deflecting speed of the convey
means on the basis of counted value, and a recovery step (steps 5,
8 in FIGS. 12 and 13) for correcting the rocking amount of the
rocking drive means rocked by the control means on the basis of
comparison between the calculated deflecting speed and a
predetermined deflecting speed and for recovering the deflecting
speed within a predetermined deflecting speed range are carried
out, whereby, even when the deflecting speed of the transfer belt
108 is fast, the belt deflection is gradually corrected to return
the convey belt to its normal position swiftly while changing the
rocking interval without causing transfer-shift.
According to the illustrated embodiment, since, when the actuator
is urged by the belt end to detect the belt deflection, the shaft
for conveying the belt is reduced by driving the pulse motor,
thereby controlling the belt deflection by changing the shifting
direction of the belt, and, since the time period during which the
belt deflection is being detected is counted so that, when the
counted value exceeds the threshold value, the rocking direction is
changed, and further since the interval between the threshold
values is changed in accordance with the number of the motor
operations to change the interval of the driving of the pulse
motor, the belt deflection can be gradually corrected without
causing the transfer-shift which may cause the deterioration of the
image when the belt deflecting direction is changed.
The present invention is not limited to the above-mentioned
embodiments, but various alterations and modifications can be
adopted within the scope of the invention.
* * * * *